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Open AccessResearch Acute and late toxicity in prostate cancer patients treated by dose escalated intensity modulated radiation therapy and organ tracking Pirus Ghadjar†, Jacqueline Vock

Open Access

Research

Acute and late toxicity in prostate cancer patients treated by dose escalated intensity modulated radiation therapy and organ tracking

Pirus Ghadjar†, Jacqueline Vock†, Daniel Vetterli, Peter Manser,

Roland Bigler, Jan Tille, Axel Madlung, Frank Behrensmeier, Roberto Mini

and Daniel M Aebersold*

Address: Department of Radiation Oncology with Division of Medical Radiation Physics, University of Bern, Inselspital, Bern, Switzerland,

Freiburgstrasse, 3010 Bern, Switzerland

Email: Pirus Ghadjar - pirus.ghadjar@insel.ch; Jacqueline Vock - Jacqueline.Vock@hcuge.ch; Daniel Vetterli - daniel.vetterli@radioonkologie.ch; Peter Manser - peter.manser@insel.ch; Roland Bigler - roland.bigler@insel.ch; Jan Tille - jan.tille@insel.ch;

Axel Madlung - axel.madlung@insel.ch; Frank Behrensmeier - frank.behrensmeier@insel.ch; Roberto Mini - roberto.mini@insel.ch;

Daniel M Aebersold* - daniel.aebersold@insel.ch

* Corresponding author †Equal contributors

Abstract

Background: To report acute and late toxicity in prostate cancer patients treated by dose

escalated intensity-modulated radiation therapy (IMRT) and organ tracking

Methods: From 06/2004 to 12/2005 39 men were treated by 80 Gy IMRT along with organ

tracking Median age was 69 years, risk of recurrence was low 18%, intermediate 21% and high in

61% patients Hormone therapy (HT) was received by 74% of patients Toxicity was scored

according to the CTC scale version 3.0 Median follow-up (FU) was 29 months

Results: Acute and maximal late grade 2 gastrointestinal (GI) toxicity was 3% and 8%, late grade

2 GI toxicity dropped to 0% at the end of FU No acute or late grade 3 GI toxicity was observed

Grade 2 and 3 pre-treatment genitourinary (GU) morbidity (PGUM) was 20% and 5% Acute and

maximal late grade 2 GU toxicity was 56% and 28% and late grade 2 GU toxicity decreased to 15%

of patients at the end of FU Acute and maximal late grade 3 GU toxicity was 8% and 3%,

respectively Decreased late ≥ grade 2 GU toxicity free survival was associated with higher age (P

= 025), absence of HT (P = 016) and higher PGUM (P < 001)

Discussion: GI toxicity rates after IMRT and organ tracking are excellent, GU toxicity rates are

strongly related to PGUM

Background

Prostate cancer (PCA) is the most commonly diagnosed

cancer among men in Europe and North America [1,2]

after skin cancer In the last decade significant

improve-ment in planning and delivery of radiotherapy (RT) such

as three-dimensional conformal RT (3D-CRT) and

inten-sity-modulated radiation therapy (IMRT) have been developed [3-5] allowing the delivery of higher radiation doses Dose escalated RT has been shown to improve bio-chemical control rates in PCA, however, to date, this has not translated into better overall survival [5-12] Dose escalated 3D-CRT has led to increased gastrointestinal

Published: 20 October 2008

Radiation Oncology 2008, 3:35 doi:10.1186/1748-717X-3-35

Received: 28 July 2008 Accepted: 20 October 2008 This article is available from: http://www.ro-journal.com/content/3/1/35

© 2008 Ghadjar et al; licensee BioMed Central Ltd

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

(GI) toxicity [10,13,14] High-dose RT for prostate cancer

delivered by IMRT causes lower acute and late GI toxicity

rates as compared to 3D-CRT [4] and improvement in

tumor delineation such as matching of an magnetic

reso-nance imaging (MRI) of the pelvis with the planning

com-puted tomography (CT) has been shown to reduce GI

toxicity in dose escalated RT due to decreased dose to the

rectal wall [15]

On the other hand localization of the prostate by image

guided radiation therapy (IGRT) is a reasonable approach

to reduce toxicity in dose escalated RT of PCA, taking into

account the interfractional variability of the prostate

posi-tion Therefore we treated prostate cancer patients with

dose escalated high precision RT by IMRT along with

organ tracking, to reduce toxicity, especially of the GI

tract This work presents the pre-treatment GI and

geni-tourinary (GU) morbidity and acute and late toxicity of

the first 39 patients after a median follow-up of 29

months

Methods

Patient selection and characteristics

A total of 46 consecutive men with histologically proven

adenocarcinoma of the prostate and cM0 stage were

treated by IMRT along with organ tracking after providing

informed consent in accordance with the standards of the

local ethics committee and with the Helsinki Declaration

of 1975, as revised in 1983 The pre-treatment staging

included a complete history, physical examination, digital

rectal examination, transrectal ultrasound (TRUS) of the

prostate, biopsy with specification of the Gleason score,

prostate-specific antigen (PSA) level, CT and/or MRI of

the abdomen and pelvis and a total-body bone scan

When clinically indicated a chest x-ray and/or thoracic CT

was performed Based on these examinations clinical

stag-ing was defined accordstag-ing to the 2002 American Joint

Committee on Cancer tumor, lymph nodes and

metasta-sis system [16] Patients were grouped according to their

risk of recurrence as recommended by the National

Com-prehensive Cancer Network practise guidelines in

oncol-ogy http://www.nccn.org Patients with multiple adverse

factors were not shifted to the next higher risk group

Seven patients with previous implantation of hip

prosthe-sis (n = 3) with changing of the treatment plan during the

treatment (n = 1) and with different dose constraints than

described below (n = 1) were excluded from the study

One patient died because of pancreatic cancer < 2 months

after RT and one patient died because of bile duct cancer

< 9 months after RT, both were also excluded because of

insufficient follow-up The study population thus

con-sisted of 39 patients, treated between 06/2004 and 12/

2005, who were retrospectively analyzed All patients

were Caucasian and no patient had received previous

pel-vic RT All patients completed the planned course of

radi-ation, receiving treatment as outlined below Median age

of the patients was 69 years (range, 54 – 81 years), median follow-up was 29 months (range, 22 – 40 months) Risk

of recurrence was low in 7 (18%), intermediate in 8 (21%) or high in 24 (61%) patients

Hormonal therapy

A total of 29 patients (74%) received hormonal therapy (HT), either neoadjuvant, concomitant or adjuvant, with

a median duration of 6 months (range, 2 – 24 months) but always during RT Twenty-six patients received com-bined androgen blockade (CAB) consisting of antiandro-gen and gonadotropin releasing hormone analogue (GnRH) Three patients received antiandrogen mono-therapy Pre-irradiation HT was given to 26 patients (67%) with a median duration of 1.5 months (range, 0.3 – 3.5 months) before starting RT

External beam radiotherapy

All 39 patients included in this study were treated using IMRT with organ tracking as described previously [17] Briefly, the dose was delivered in daily fractions of 2 Gy, given five sessions per week, to a total of 80 Gy Prior to the treatment, three gold markers (diameter = 0.9 mm, length = 7 mm) were implanted into the prostate of every patient under TRUS guidance Thirty six of 39 patients underwent an MRI scan of the pelvis in our radiology department In these patients, digital data was used for image fusion with the planning CT scan To produce high-resolution digitally reconstructed radiographs (DRRs), consecutive CT images (GE Prospeed®) with an interslice spacing and thickness of 3 mm were obtained To estimate the risk for seminal vesicle (SV) invasion, the Roach for-mula [18] was calculated for each patient If the risk for SV invasion was > 15%, as it was the case in 21 patients, the proximal third of the SV was included to the clinical target volume (CTV) electively If invasion of the base of the SV was seen in the MRI (cT3b), the whole SV were electively included to the CTV The planning target volume (PTV) was then delineated by encompassing the prostate with 5

mm safety margins in all directions but dorsal, where a 3

mm margin was added In addition to the PTV, the walls

of the rectum and bladder, the femoral heads and the skin surface were also identified A coplanar five-field IMRT technique with fields placed at angles of 45°, 90°, 180°, 270°, and 320° was used to treat prostate cancer patients with 15MV X-rays (Clinac 2300C/D, Varian Medical Sys-tems) The dose was applied by the dynamic MLC tech-nique using an 80 leaf-MLC The 80 Gy were prescribed to the median of the PTV More than 99% of the PTV volume was included in the 95% isodose and the maximum dose was limited to 105% To limit the dose to the organs at risk (OAR), a template was used with a set of dose con-straints Daily treatment was intended with a full bladder The isocenter was placed 7 cm behind the symphysis and

at the height of the cranial end of the opening of the

foramen obturatorium Partial DRRs were generated for

all treatment beams and in addition for two extra setup

beams from the anterior-posterior (AP) and the lateral

direction (LAT) The field size of the AP setup field was

chosen to encompass the implanted markers with a

mar-gin of about 1.5 cm The LAT field enclosed the markers

and the symphysis With a drawing tool the marker

posi-tions were manually highlighted, serving as a layer

struc-ture for subsequent portal image evaluation The two

setup DRRs served as a reference for portal images taken

before daily treatment For isocenter verification, the

patients were simulated (Ximatron®, Varian Medical

Sys-tems) using the two additional setup fields The isocenter

was then marked on the patient's skin In the treatment

room, the patients were aligned on a carbon-fiber couch

panel within their immobilization device using the skin

marks Before each treatment fraction the two setup fields

were acquired using the aS500® portal imager (Varian

Medical Systems) with a dose saving acquisition mode

The setup and correction of patients position was

per-formed as previously described [19] Briefly, setup images

from the AP and LAT direction were taken with the 6 MV

beam A comparison between positions of the fiducial

markers on the portal image with the corresponding

refer-ence DRR followed Patient position was then manually

adjusted in all 3 dimensions until the best center of mass

(CM) alignment was found with a CM >1 mm limit in any

direction Following this sequential setup procedure, the patient was treated with the multi-field IMRT plan Opti-mization of the IMRT plan included a dose limit within the central periurethral area of 99% of the prescribed dose The duration of IMRT reached a median of 56 days (range, 52 – 63 days)

Dose constraints

A maximum dose of 100% to the urethra was allowed For the rectal wall (from the ischial tuberosity to the bottom

of the sacroiliac joint), constraints described by Leibel et

al [5] and Boersma et al [13] were used: the median V47 (percentage of the rectal wall receiving at least 47 Gy) was set to <53% and the median V75 to <5% For the bladder the constraint from Leibel et al was used: the median V47 (percentage of bladder wall receiving at least 47 Gy) was set to <53%

To assess coverage, homogeneity and conformity of the PTV the V95 (percentage of PTV receiving at least 95% of dose, corresponding to 76 Gy) and the Dmax and Dmin (maximum and minimum dose within the PTV) were cal-culated from the dose volume histograms

Follow-up protocol

Patients were seen by a radiation oncologist at least weekly during the RT Follow-up visits were arranged 2–4 weeks after completion of IMRT and every 3 to 6 months

Table 1: Patient characteristics

Age

≤ 69 years 20 (51.3%)

> 69 years 19 (48.7%)

Tumor stage

cT1 12 (30.8%)

cT3a 13 (33.4%) cT3b 7 (17.9%) cT4 2 (5.1%)

Gleason score

2–6 20 (51.3%)

7 13 (33.3%) 8–10 6 (15.4%)

Pre-treatment PSA

≤ 10 ng/mL 20 (51.3%)

>10 ng/mL 19 (48.7%)

Risk group

Low 7 (17.9%) Intermediate 8 (20.5%) High 24 (61.6%)

Hormonal therapy

no 10 (25.6%) yes 29 (74.4%)

Median FU months† (range) 29 (22–40) Abbreviations: PSA = prostate- specific antigen; FU = follow-up;

†period after completion of treatment.

for the first 2 years and annually thereafter with a digital

rectal examination and a serum PSA level obtained at each

visit Patients alternated follow-up visits between their

urologist and radiation oncologist A minority of patients

who did not attend these visits were contacted and data

were successfully retrieved

Toxicity scoring

Toxicity was graded using the common terminology

crite-ria for adverse events (CTC AE) version 3.0 http://

ctep.cancer.gov/forms/CTCAEv3.pdf from the National

Cancer Institute Late toxicity was defined as

complica-tions occurring three months after the end of treatment

Late toxicity at last follow-up visit was determined and

was termed last late toxicity This was done to assess

whether the late toxicity was persistent or was transient

Statistical analysis

Descriptives include absolute and relative frequencies for

categorical variables, median and range for quantitative

variables

The primary endpoint was the occurrence of acute and late

≥ grade 2 GI and GU toxicity For statistical analysis age (≤

vs > 69 years), PTV (≤ vs > 105 cm3), PTV Dmax (≤ vs >

84.3 Gy) and bladder V47 (≤ vs >28%) were grouped

according to the median Pre treatment GU toxicity

(PGUM) (grade 0–1 vs grade 2–3) and acute and late GU toxicity (grade 0–1 vs grade 2–3) were grouped Acute GU toxicity and PGUM were compared using the Fisher's exact test Estimation of actuarial rates for late ≥ grade 2 GU

tox-Table 3: Pre-treatment genitourinary morbidity and genitourinary acute and late toxicity

Dysuria 0 36 (92) 20 (51) 35 (90) 38 (97)

1 3 (8) 13 (33) 4 (10) 1 (3)

Incontinence 0 34 (87) 33 (84) 34 (87) 37 (94)

1 4 (10) 5 (13) 4 (10) 1 (3)

Retention 0 20 (51) 16 (41) 23 (59) 34 (86)

1 13 (33) 9 (23) 11 (28) 3 (8)

2 5 (13) 12 (31) 4 (10) 1 (3)

Frequency/urgency 0 23 (59) 6 (15) 17 (44) 23 (59)

1 13 (33) 16 (41) 15 (38) 14 (36)

2 2 (5) 15 (39) 7 (18) 2 (5)

Hematuria 0 39 (100) 39 (100) 36 (92) 37 (95)

Highest GU* 0 15 (39) 1 (3) 11 (28) 19 (49)

1 14 (36) 13 (33) 16 (41) 13 (33)

2 8 (20) 22 (56) 11 (28) 6 (15)

Abbreviations: Pre-Tx = pre-treatment; * The highest toxicity in a patient was counted as a single event; † During therapy and until 3 months after completion; ‡ maximal late toxicity > 3 months after completion of therapy; § Incidence of late toxicity at last follow-up visit

Table 2: Pre-treatment gastrointestinal morbidity and gastrointestinal acute and late toxicity

Toxicity Grade n (%) n (%) n (%) n (%) Diarrhea 0 39 (100) 29 (74) 36 (92) 38 (97)

1 0 9 (23) 3 (8) 1 (3)

2 0 1 (3) 0 0 Rectal pain 0 38 (97) 34 (87) 37 (96) 38 (97)

1 1 (3) 5 (13) 1 (3) 1 (3)

2 0 0 1 (3) 0 Rectal bleeding 0 36 (92) 36 (92) 33 (85) 34 (87)

1 3 (8) 3 (8) 4 (10) 5 (13)

2 0 0 2 (5) 0 Highest GI* 0 36 (92) 25 (64) 30 (77) 32 (82)

1 3 (8) 13 (33) 6 (15) 7 (18)

2 0 1 (3) 3 (8) 0 Abbreviations: Pre-Tx = pre-treatment; * The highest toxicity in a patient was counted as a single event; † During therapy and until 3 months after completion; ‡ maximal late toxicity > 3 months after completion of therapy; § Incidence of late toxicity at last follow-up visit

icity free survival was calculated using the Kaplan-Meier

product limit methodology Kaplan-Meier rates were

compared using the log-rank test [20] Cox regression

models were used to determine independent prognostic

factors for decreased late ≥ grade 2 GU toxicity free

sur-vival [21] Variables were included to the model if the

uni-variate P-value was <.1, thus, age, HT and PGUM were

included Backward model selection was performed in

order to identify predictors for decreased ≥ grade 2 late GU

toxicity free survival Statistical significance was

consid-ered on a two-sided level of α = 0.05 Statistical analysis

was performed with SPSS version 16.0 (SPSS Inc.,

Chi-cago, IL)

Results

Coverage, homogeneity and conformity of the PTV

For the PTV, the median V95 was 97.9% (range, 89.2 –

99.8%) Median Dmax and Dmin were 84.3 Gy (range,

82.2–85.4 Gy) and 72.1 Gy (range, 67.5 – 74.6 Gy),

respectively

Acute and late GI Toxicity

Patient characteristics are summarized in Table 1 The

pre-treatment GI morbidity, acute and late GI toxicity and

incidence of late GI toxicity at last follow-up visit are

sum-marized in Table 2 Incidence of single symptoms

(diarrhea, rectal pain, rectal bleeding) as well as the

high-est toxicity occurred in a given patient concluding all

sin-gle symptoms but counting only the highest toxicity as a

single event are depicted Acute grade 2 GI toxicity was 1

(3%) and maximal late grade 2 GI toxicity was 3 (8%) No

grade 3 GI toxicity occurred The median time from the

completion of RT to the occurrence of ≥ grade 1 late GI

was 14 months (range, 6 – 30 months) Late GI toxicity

decreased as time from treatment elapsed At last

follow-up visit the incidence of late grade 2 GI toxicity was 0%

There was no association observed between clinical or

dosimetric parameters and acute GI toxicity or late GI tox-icity free survival

Acute and late GU Toxicity

The PGUM and acute and late GU toxicity are summarized

in Table 3 Incidence of single symptoms (dysuria, incon-tinence, retention, frequency/urgency, hematuria) as well

as the highest toxicity occurred in a given patient conclud-ing all sconclud-ingle symptoms but countconclud-ing only the highest tox-icity as a single event are depicted Before treatment 8 patients (20%) had grade 2 and 2 patients (5%) had grade

3 PGUM After treatment acute grade 2 GU toxicity occurred in 22 (56%) and maximal late grade 2 in 11 (28%) patients Acute and maximal late grade 3 GU toxic-ity occurred in 3 (8%) and 1 (3%) patients, respectively There was no grade 4 GU toxicity observed The median time from the completion of RT to the occurrence of late

≥ grade 2 GU toxicity was 12 months (range, 4 – 26 months)

Interestingly late GU toxicity decreased as time from treat-ment elapsed At the last follow-up visit only 6 (15%) of patients had late grade 2 and 1 (3%) had late grade 3 GU toxicity, being fewer patients than initially observed with grade 2 or 3 PGUM The patient who developed late grade

3 GU toxicity had a bulbar urethral stricture and was treated twice by urethral dilatation, however obstructive

Table 5: Multiple Cox regression analysis of factors associated with late ≥ grade 2 GU toxicity free survival

Age > 69 years versus ≤ 69 years 2.7 0.7–10.9 143 Hormonal therapy no versus yes 12.4 2.4–64.6 003 PGUM grade 2-3 versus grade 0–1 29.1 5.4–156.8 <.001 Abbreviation: RR = relative risk; CI = 95% RR confidence intervals; PGUM = pre-treatment genitourinary morbidity.

Table 4: Factors correlating with three year grade ≥ 2 GU toxicity free survival in univariate analysis

Abbrevations: TFS = toxicity free survival; PGUM = pre-treatment genitourinary morbidity; PTV = planning target volume; PTV Dmax = maximum dose within the PTV; Bladder V47 = percentage of bladder wall receiving at least 47 Gy * Number at risk at three years; † Log-rank test

symptoms were persistent and ever since the patient uses

daily self-catheterism

Factors associated with GU toxicity

There was an association of PGUM and acute ≥ grade 2

GU toxicity (P = 007) but not with the other tested

parameters age, HT, PTV, PTV Dmax or bladder V47

Decreased grade ≥ 2 late GU toxicity free survival was

asso-ciated with higher age (P = 025), absence of HT (P = 016)

and higher PGUM (P < 001) but not with the PTV, PTV

Dmax or bladder V47 (Table 4; Figure 1) In multiple Cox

regression analysis higher PGUM (P < 001) and absence

of HT (P = 003) were independently associated with

decreased late ≥ grade 2 GU toxicity free survival (Table 5)

PSA nadir

With a median follow-up of 29 months it is too early to report biochemical control rates However, after treatment 93% (27 out of 29) of patients with and 90% (9 out of 10)

of patients without HT reached a PSA nadir value ≤ 0.5 ng/

mL In patients treated by HT, time to nadir was shorter (P

< 001) and the nadir value was lower (P = 001) as com-pared to patients without HT The median time to nadir was 23.6 months (range, 3.3 – 26.1 months) in patients without and 4.0 months (range, 0.0 – 24.4 months) in patients with HT The median nadir value was 0.3 ng/mL (range, 0.05 – 5.1 ng/mL) in patients without and 0.07 ng/mL (range, 0.0 – 0.95 ng/mL) in patients with HT

Discussion

With the use of more conformal RT techniques, high dose

RT of PCA has become the accepted standard of care Simultaneously, the incidence of treatment related toxic-ity has become even more important Here we report the pre-treatment GI and GU morbidity and acute and late toxicity in patients treated by dose escalated high preci-sion RT by IMRT along with organ tracking The grade 2 acute and maximal late GI toxicity rates were 3% and 8% and late grade 2 GI toxicity decreased to 0% at the end of the follow-up with no grade 3 GI toxicity observed In face

of the grade 2 and 3 PGUM rates of 20% and 5% the observed acute and late grade 2 GU toxicity rates were 56% and 28% Interestingly the late grade 2 GU toxicity rate dropped to 15% at the end of follow-up being even below the PGUM reported Acute and late grade 3 GU icity was 8% and 3%, respectively The use of different tox-icity scales and RT techniques makes it difficult to compare our data to other studies Only two studies have reported toxicity rates after PCA treatment with 3D-CRT or IMRT using fiducial markers for position verification [22,23] Table 6 summarizes the observed toxicity in these studies in comparison with the results of our study Con-cerning acute and late GI toxicity our results are excellent, but the maximal GU toxicity rates are higher than those described elsewhere However, the PGUM in our patient cohort was relatively high and if this is considered, the GU toxicity rates observed in our patients are comparable to those in the literature The acute GU toxicity was associ-ated with PGUM and the ≥ grade 2 late GU toxicity free survival was significantly decreased in patients with higher age, higher PGUM and in patients who were not treated by HT The decreased rate of GU late effects in patients undergoing HT is in accordance with pooled data from RTOG trials 85-31, 86-10 and 92-02, where the addi-tional use of HT decreased GU toxicity [24] The impact of

HT on the late GU toxicity might depend on the extent of PGUM, being beneficial especially in patients with obstructive symptoms The high amount of patients with pre-treatment obstructive symptoms (grade 1 – 3: 49%)

Actuarial analysis of three year late ≥ grade 2 GU toxicity

free survival stratified by (a) pre-treatment genitourinary

morbidity (PGUM) and (b) by history of hormonal therapy

Figure 1

Actuarial analysis of three year late ≥ grade 2 GU

toxicity free survival stratified by (a) pre-treatment

genitourinary morbidity (PGUM) and (b) by history

of hormonal therapy.

might therefore account for the association of HT with

decreased GU toxicity

We are aware of the obvious limitations of our study,

being the relatively small number of patients analyzed

and the retrospective nature of the study We also

recog-nize that longer follow-up will be needed to compare the

tumor control rates with those after different treatment

regiments Nevertheless, this report provides strong

evi-dence for the need of reporting pre-treatment morbidity

rates along with the observed toxicity rates to enhance

comparability with other studies

Conclusion

GI toxicity rates after dose escalated IMRT and organ

track-ing are excellent Acute and late GU toxicity are

compara-ble to other reported series when the pre-treatment GU

morbidity is considered

Competing interests

The authors declare that they have no competing interests

Authors' contributions

Each author had participated sufficiently in the work to

take public responsibility for appropriate portions of the

content PG, JV and DMA designed the study PG, JT and

RB performed the statistical analysis PG, JV, JT, RB, DV,

PM, RM, AM and FB collected the data and together with

DMA interpreted the data The manuscript was written by

PG, all other authors helped and finally approved the

final manuscript

References

1 Bracarda S, de Cobelli O, Greco C, Prayer-Galetti T, Valdagni R,

Gatta G, de Braud F, Bartsch G: Cancer of the prostate Crit Rev

Oncol Haematol 2005, 56:379-396.

2. Jemal A, Siegel R, Ward E, Murray T, Xu J, Smigal C, Thun MJ: Cancer

statistics, 2006 CA Cancer J Clin 2006, 56:106-130.

3. D' Amico AV, Hanks GE: Three-dimensional conformal

radia-tion therapy for prostate cancer In Radiotherapeutic management

of prostate adenocarcinoma Boston: Arnold; 1999:21-50

4 Zelefsky MJ, Fuks Z, Happersett L, Lee HJ, Ling CC, Burman CM,

Hunt M, Wolfe T, Venkatraman ES, Jackson A, Skwarchuk M, Leibel

SA: Clinical experience with intensity modulated radiation

therapy (IMRT) in prostate cancer Radiother Oncol 2000,

55:241-249.

5 Leibel SA, Fuks Z, Zelefsky MJ, Hunt M, Burman CM, Mageras GS,

Chui CS, Jackson A, Amols HI, Ling CC: Technological advances

in external-beam radiation therapy for the treatment of

localized prostate cancer Semin Oncol 2003, 30(5):596-615.

6 Shipley WU, Verhey LJ, Munzenrider JE, Suit HD, Urie MM, McManus

PL, Young RH, Shipley JW, Zietman AL, Biggs PJ, et al.: Advanced

prostate cancer: The results of a randomized comparative trial of high dose irradiation boosting with conformal pro-tons compared with conventional dose irradiation using

pho-tons alone Int J Radiat Oncol Biol Phys 1995, 32:3-12.

7 Hanks GE, Hanlon AL, Schultheiss TE, Pinover WH, Movsas B, Epstein

BE, Hunt MA: Dose escalation with 3D conformal treatment:

5 year outcomes, treatment optimization, and future

direc-tions Int J Radiat Oncol Biol Phys 1998, 41:501-510.

8 Zelefsky MJ, Leibel SA, Gaudin PB, Kutcher GJ, Fleshner NE,

Venkat-ramen ES, Reuter VE, Fair WR, Ling CC, Fuks Z: Dose escalation with three-dimensional conformal radiation therapy affects

the outcome in prostate cancer Int J Radiat Oncol Biol Phys 1998,

41:491-500.

9 Zelefsky MJ, Fuks Z, Hunt M, Lee HJ, Lombardi D, Ling CC, Reuter

VE, Venkatraman ES, Leibel SA: High dose radiation delivered by intensity modulated conformal radiotherapy improves the

outcome of localized prostate cancer J Urol 2001,

166:876-881.

10 Pollack A, Zagars GK, Starkschall G, Antolak JA, Lee JJ, Huang E, von

Eschenbach AC, Kuban DA, Rosen I: Prostate cancer radiation dose response: Results of the M D Anderson phase III

rand-omized trial Int J Radiat Oncol Biol Phys 2002, 53:1097-1105.

11 Sathya JR, Davis IR, Julian JA, Guo Q, Daya D, Dayes IS, Lukka HR,

Levine M: Randomized trial comparing iridium implant plus external-beam radiation therapy with external-beam radia-tion therapy alone in node-negative locally advanced cancer

of the prostate J Clin Oncol 2005, 23:1192-1199.

12 Zietman AL, DeSilvio ML, Slater JD, Rossi CJ Jr, Miller DW, Adams

JA, Shipley WU: Comparison of conventional-dose vs high-dose conformal radiation therapy in clinically localized ade-nocarcinoma of the prostate: A randomized controlled trial.

JAMA 2005, 294:1233-1239.

13 Boersma LJ, Brink M van den, Bruce AM, Shouman T, Gras L, te Velde

A, Lebesque JV: Estimation of the incidence of late bladder and rectum complications after high-dose (70–78 GY) conformal radiotherapy for prostate cancer using dose-volume

histo-grams Int J Radiat Oncol Biol Phys 1998, 41:83-92.

14. Storey MR, Pollack A, Zagars G, Smith L, Antolak J, Rosen I: Compli-cations from radiotherapy dose escalation in prostate

can-cer: preliminary results of a randomized trial Int J Radiat Oncol

Biol Phys 2000, 48:635-42.

15 Steenbakkers RJ, Deurloo KE, Nowak PJ, Lebesque JV, van Herk M,

Rasch CR: Reduction of dose delivered to the rectum and bulb

of the penis using MRI delineation for radiotherapy of the

prostate Int J Radiat Oncol Biol Phys 2003, 57:1269-79.

16. Sobin LH, Wittekind CH: The prostate In TNM Classification of

Malignant Tumors New York, Wiley-Liss; 2002:184-187

17 Vetterli D, Riem H, Aebersold DM, Greiner RH, Manser P, Cossmann

P, Kemmerling L, Born EJ, Mini R: Introduction of a novel dose saving acquisition mode for the PortalVision aS500 EPID to

facilitate on-line patient setup verification Med Phys 2004,

31:828-31.

Table 6: Comparison of acute and late GI and GU toxicity rates with the literature

(months)

grade 2/3

Late GI grade 2/3

Acute GU grade 2/3

Late GU grade 2/3

Ref

Skala et al 690 3D/IMRT ≤ 79.8 37# RTOG n.a 2.5%/0.7% n.a 8.8/0.9 22 Lips et al 331 IMRT 76 47* CTC/RTOG 1 30%/0 9%/1% 47%/3% 2 21%/4% 2 23 Current

study

39 IMRT 80 29# CTC 3%/0 8%/0 61%/3% 26%/3%

Abbreviations: GI = gastrointestinal; GU = genitourinary; Pts = patients; RT = radiotherapy; FU = follow-up; Tox = toxicity score used; Ref = reference; 3D = three-dimensional conformal radiation therapy; IMRT = intensity modulated radiation therapy; RTOG = Radiation Therapy Oncology Group toxicity criteria; n.a = not applicable; CTC = Common Toxicity Criteria; # median (months); * mean (months); 1 For acute toxicity CTC criteria were used and for late toxicity RTOG criteria 2 plus 0.3% of patients with grade 4 toxicity.

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18. Roach M 3rd: Re: The use of prostate specific antigen, clinical

stage and Gleason score to predict pathological stage in men

with localized prostate cancer J Urol 1993, 150:1923-24.

19 Vetterli D, Thalmann S, Behrensmeier F, Kemmerling L, Born EJ, Mini

R, Greiner RH, Aebersold DM: Daily organ tracking in

intensity-modulated radiotherapy of prostate cancer using an

elec-tronic portal imaging device with a dose saving acquisition

mode Radiother Oncol 2006, 79:101-108.

20. Harris EK, Albert A: Survivorship analysis for clinical studies.

New York, NY: Marcel Dekker; 1991:5-125

21. Cox DR, Oakes D: Analysis of survival data London, United

Kingdom: Chapman and Hall; 1984:110-120

22 Skala M, Rosewall T, Dawson L, Divanbeigi L, Lockwood G, Thomas

C, Crook J, Chung P, Warde P, Catton C: Patient-assessed late

toxicity rates and principal component analysis after

image-guided radiation therapy for prostate cancer Int J Radiat Oncol

Biol Phys 2007, 68:690-698.

23 Lips IM, Dehnad H, van Gils CH, Boeken Kruger AE, Heide UA van

der, van Vulpen M: High-dose intensity-modulated

radiother-apy for prostate cancer using daily fiducial marker-based

position verification: acute and late toxicity in 331 patients.

Radiat Oncol 2008, 3:15.

24. Lawton CA, Bae K, Pilepich M, Hanks G, Shipley W: Long-term

treatment sequelae after external beam irradiation with or

without hormonal manipulation for adenocarcinoma of the

prostate: Analysis of Radiation Therapy Oncology Group

studies 85-31, 86-10, and 92-02 Int J Radiat Oncol Biol Phys 2008,

70:437-41.